Abstract
Four different applications of spectral proper orthogonal decomposition (SPOD) are demonstrated on large-eddy simulation data of a turbulent jet. These are: low-rank reconstruction, denoising, frequency–time analysis and prewhitening. We demonstrate SPOD-based flow-field reconstruction using direct inversion of the SPOD algorithm (frequency-domain approach) and propose an alternative approach based on projection of the time series data onto the modes (time-domain approach). We further present a SPOD-based denoising strategy that is based on hard thresholding of the SPOD eigenvalues. The proposed strategy achieves significant noise reduction while facilitating drastic data compression. In contrast to standard methods of frequency–time analysis such as wavelet transform, a proposed SPOD-based approach yields a spectrogram that characterises the temporal evolution of spatially coherent flow structures. A convolution-based strategy is proposed to compute the time-continuous expansion coefficients. When applied to the turbulent jet data, SPOD-based frequency–time analysis reveals that the intermittent occurrence of large-scale coherent structures is directly associated with high-energy events. This work suggests that the time-domain approach is preferable for low-rank reconstruction of individual snapshots, and the frequency-domain approach for denoising and frequency–time analysis.
Highlights
The curse of dimensionality in the analysis of large turbulent flow data has led to the development of a number of modal decomposition A26-1A
We demonstrate the use of spectral proper orthogonal decomposition (SPOD) for denoising on surrogate data obtained by imposing high levels of additive Gaussian noise on simulation data
Different applications of SPOD including low-rank reconstruction, denoising, prewhitening and frequency–time analysis are demonstrated for the example of large-eddy simulation (LES) data of a turbulent jet
Summary
The curse of dimensionality (see e.g. Meneveau, Lund & Moin 1992) in the analysis of large turbulent flow data has led to the development of a number of modal decomposition. Low-dimensional reconstructions from standard POD have been applied for this purpose to flow past a backward-facing step (Kostas, Soria & Chong 2005), arterial flows (Charonko et al 2010; Brindise et al 2017), turbulent wakes (Raiola et al 2015) and vortex rings (Stewart & Vlachos 2012; Brindise & Vlachos 2017) In this contribution, we demonstrate the use of SPOD for denoising on surrogate data obtained by imposing high levels of additive Gaussian noise on simulation data. We demonstrate that SPOD-based denoising combines certain advantages of temporal filters and standard POD-based denoising Owing to their chaotic nature, turbulent flows are characterised by high levels of intermittency. The four different applications, SPOD-based low-dimensional reconstruction, denoising, frequency–time analysis and prewhitening, are demonstrated in § 3.1, § 3.2, § 3.3 and § 3.4, respectively.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
